DE3303217A1 - Corrosion inhibitor based on calcined hydraulic lime - Google Patents

Abstract

Coating agents containing ground, calcined, hydraulic or highly hydraulic lime without sulphate addition as a corrosion-inhibiting component.

Description

Corrosion protection agent on the basis of fired

Ifydraulic lime cements are known to have anti-rust properties exhibit. This is e.g. B. for the durability of the reinforcement in reinforced and prestressed concrete crucial and is z. 13. Also in the form of cement mortar linings in steel pipes applied. The anti-rust property of cement hydration products is based on the basic environment through calcium hydroxide, which occurs in the reaction of calcium silicates is formed with water.

With thin, z. B. is only about 1 mm thick coatings on steel this anti-corrosion effect in the atmosphere usually does not last long. The effects of Co2 and SO2 from the atmosphere neutralize relatively quickly the calcium hydroxide. In particular, calcium carbonate is formed. The pH drops. At the same time, the calcium aluminosulfate hydrates that are initially formed can decompose in the neutral and acidic range in the presence of moisture, corrosive Sulphate is formed. There is therefore a need for an improved coating agent for the corrosion protection provided by the invention.

The coating composition according to the invention for corrosion protection is characterized in that it is ground as a corrosion-inhibiting component Contains burnt hydraulic or hydraulic lime without added sulphate.

A hydraulic lime with a sulfate content of c 1% as well as with high proportions of calcium aluminate and / or calcium aluminate ferrite.

Preferred grain sizes are between about 20 and about 50 μm.

About hydraulic or Ilochhydraulic lime can be beneficial as aqueous suspension, preferably with a low water content, optionally customary Fillers and additives are used.

It is advantageous if the suspension is further anoryanic Contains binders, in particular Portland cement clinker powder and / or air lime.

This is a further embodiment of the coating agent characterized in that the hydraulic or highly hydraulic lime in aqueous dispersion or an emulsion of predominantly unsaponifiable plastics, optionally in a mixture with other pigments, common fillers and additives and / or inorganic binders, in particular l'ort landzementklinkerrnehl and / or air lime is present.

This is a further embodiment of the coating agent characterized in that the hydraulic or hydraulic lime conventional solvent-based Coating materials, preferably on the basis of unsaponifiable bituminous Materials and / or plastics, alone or in admixture with other pigments, fillers and / or inorganic binders, in particular port land cement powder and / or Air lime, is added.

This provides a further embodiment of the coating agent characterized in that the hydraulic and high hydraulic lime reaction hardening Synthetic resin binders, preferably epoxy resin, polyester resin, polymethyl methacrylate resin, alone or in a mixture with other pigments, fillers and / or inorganic Binding agents, in particular port land cement powder and / or air lime, added is.

Burnt hydraulic lime is known to be produced by burning at about 1000 - 1200 C and consists almost exclusively of the phases calcium hydroxide, Dicalcium aluminate, calcium aluminate and calcium aluminate ferrite. Has calcium hydroxide a proportion of about 25 to 60! .lasse-t, in the case of highly hydraulic lime in the lower Area. The rest are the hydraulically reacting phases.

Hydraulic limes have similarities with Portland cements, but also decisive differences, which is why they z. B. recorded in separate standards will. There are decisive differences in production and composition and to name the properties. Cements are burned at temperatures that match that Melt some of the material (about a quarter to a third). Hydraulic limes are burnt below the sintering temperature. In terms of quantity The predominant phase (r50 mass%) in Portland cement is the? 'ricalciw; isilicate (alite); this phase does not contain hydraulic lime at all. The strength developments Portland cements far exceed those of hydraulic limes. Such high However, cement strengths are usually not required for coatings, they can even be detrimental.

Compared to cements, they offer corrosion inhibitors according to the invention Limes used have the advantage of a larger proportion of Ca (oil) 2. With the hydraulic On the one hand, lime already contains a considerable proportion of Ca (011) 2 in the binding agent on the other hand, additional Ca (CO) 2 is generated by the reaction with water educated. (Dicalcium silicate + ZVasser - calcium silicate hydrate + calcium hydroxide). Another advantage is that the dicalcium silicate is relatively inert. All in all the Ca (OII) 2 supply with hydraulic limes is greater than with cements and thus the corrosion protection effect more favorable. Compared to the use of The hydraulic limes offer pure Ca (OIi) 2 the advantage of higher strength and the gradual formation of the anti-corrosive Ca (011) 2.

Furthermore, the content of sulfate in anti-corrosion coatings important because free sulfate is known to have a corrosive effect in aqueous solution. While commercially available cements about 6 to 10 W calcium sulfate are added, As a rule, no sulphates are ground into the hydraulic limes, since with them, Due to the high Ca (OH) 2 content, the solidification is also delayed sulfate-free will. Ilydraulic lime is therefore opposed to sulphate-containing cements themselves Low-sulphate clay powder is better suited for corrosion protection, as a larger approx (OIl) 2 offer is available.

Within the hydraulically hardening limes, DIN 1060 differentiated lVasserka 1k hydraulic lime Highly hydraulic lime.

The proportions of the so-called ilydraulic factors increase in the same order (SiO2, Al203, Fe203) and thus the strength development.

Ilochhydraulic limes can harden up to about 70% hydraulically Shares included. - These hydraulically hardening phases are dicalcium silicate as well as tricalcium aluminate and calcium aluminate ferrite. While the dicalcium silicate Ca (OH) 2, which protects against corrosion, is split off when it is hydrated, calcium aluminate can and calciuraluminate ferrite in their dehydration as well as in later reactions Bind chloride and sulfate. When using the coating compositions according to the invention on the base of liydraulic lime becomes an additional one Corrosion protection causes. Corrosive chlorides from the environment and sulfates can be used in the anti-corrosion coating obtained according to the invention from calcined hydraulic limes are bound, especially with formation of compounds of the general formula 3CaO. (Al203, Fe203). (CaSO4, CaCl2). 12 1s2 ° For this reason, a hydraulically hardening lime is used with high calcium aluminate and calcium aluminate ferrite content to be preferred.

Are still of importance for the anti-corrosive effect the particle sizes of the ground binder. Small grain sizes make it easier the filling and smoothing of rough surfaces, e.g. 13. After sandblasting, against grain sizes that are too small, due to rapid complete dilation, result in only a relatively short anti-corrosion effect. The reaction margin (llydratation depth), which forms around hydraulically reacting particles, grows roughly with the square root from the time, it amounts to z. B.

after 28 days 5 S »m after 1 year N8 8 to after 5 years ~ 10 cm.

The limes used should therefore preferably be hydraulically hardening Have particles with a grain size of 20 - 50 lun, which means that they protect against corrosion Effect extended favorably.

The type of application is also essential for the protective effect. It A corrosion protection light that is as dense as possible must be sought for each application will. If hydraulic lime is used alone, with other inorganic binders mixed and / or used with only the addition of other substances, the result is a porous one Product. The porosity increases with the proportion of that added during processing Amount of water. It should therefore use the lowest possible binder: water ratio to be worked. to increase the durability of the corrosion protection effect. A longer-term moisturizing of this corrosion protection layer results in a higher one Tightness.

When adding other substances, e.g. B. other inorganic binders, Care must be taken that only the lowest possible sulfate content is added will.

An improvement in the coating properties is achieved through the addition Unsaponifiable or difficult to saponify plastic dispersions or emulsions. on the saponification resistance of the plastics is because of the calcium hydroxide present to pay attention. These additions in particular prevent the early evaporation of the Water and shrinkage are reduced, the tightness and adhesive strength are increased.

The duration of the corrosion protection rkang can be increased if such Layers, which may also contain other inorganic binders, plastic dispersions or emulsions and other additives, thereby further increasing, that they are covered with a CO2-braking or CO2-blocking film. Ilierzu are suitable e.g. B. dissolved acrylates; they reduce or

prevent the carbonation of the calcium hydroxide (conversion of the Calcium hydroxide in calcium carbonate by CO2 e.g. B. from the air) and thus cause the longer retention of the high pll value of around 12. Also can such coatings ensure longer moisture retention and thus more complete hydration 1 with denser structures can be achieved.

The hydraulic lime is also well suited as an anti-corrosion pigment or filler for rust protection paints with organic solvents dissolved in organic solvents Binders. Here too, preference is given to unsaponifiable organic coating materials to be used, such as corresponding plastics, bitumen or tar. Even when it's hot too Hydraulic lime can increase the protective effect of processing bitumen and tars.

For reaction-hardening plastics such as epoxy resins, polyurethanes, unsaturated polyesters and polymethyl methacrylates boosts hydraulic lime The protective effect is also used as an anti-corrosive pigment or filler.

The coating materials of the invention are not just for corrosion protection suitable on steel, they can also be used advantageously on other building materials and materials can be used. Z. 13. can have good adhesion and degradation on concrete permeability can be achieved. The lower permeability caused by the Coating on the concrete surface and z. T. is effected in the beet pores, slows down the rate of carbonation and thus contributes to the elongation the corrosion protection of the steel reinforcement in the concrete.

Example 1 50 parts of highly hydraulic lime are mixed with 50 parts of quartz sand graduated grain sizes (0-5 mm) and 15 parts of a defoamed aqueous acrylate dispersion (50 parts of solid, 50 parts of water) and so much water added and homogeneous mixed so that an easily workable fine mortar consistency is created. By addition of thixotropic and water-retaining agents, e.g. 13th

0.1 part of methyl cellulose, the processability can be improved. - The material can be brushed or sprayed as an anti-corrosion coating material be used.

Example 2 25 parts by weight hydraulic lime, 15 parts by weight Portland cement PZ 45 F, 45 parts by weight of quartz powder 0-200 ij and 15 parts by weight of quartz sand 0.08-0.25 rsun, together with additions of 0.5 part by weight of sodium nitrite, 0.05 part by weight Methyl cellulose and 0.05 part by weight of high molecular weight polyethylene glycol to one Mixed powder mixture. 100 parts by weight of this powder mixture have 30 C; ew.-parts a defoamed, saponification-resistant non-resin dispersion mixed homogeneously. The spreadability is adjusted with about 5 parts by weight of water.

Example 3 45 parts by weight of highly hydraulic lime and 55 parts by weight of quartz powder 0-300 ii with 50 parts by weight of an aqueous bitumen emulsion with a solids content of about 30% by weight mixed homogeneously until an easily spreadable fine-grained icon istence arises which has anti-corrosion properties.

Example 4 68 parts by weight of solvent-free epoxy resin on the basis of bisphenol A with 7 parts by weight of butylphenyl diglycidyl ether, 25 parts by weight harder based on dimethyldiaminodicyclohexylmethane and mixed with each 85 uew. Parts of hydraulic lime and quartz powder of grain size 0-200 p intimately mixed. In order to achieve sufficient stability and good spreadability modified with 0.5-1% Sylodex. The mixture of substances has anti-corrosive properties.

Claims (9)

1> A tent claims X Coating agent for corrosion protection, characterized in that it is ground as a corrosion-inhibiting component Contains burned hydraulic or highly hydraulic salk without added sulphate. 2. Coating agent for corrosion protection according to claim 1, characterized in that the ilydraulic or highly hydraulic lime has a sulfate content of <1%. 3. Coating agent for corrosion protection according to claim 1 and 2, characterized in that the hydraulic or highly hydraulic lime contains high proportions of calcium aluminate and / or calcium aluminate ferrite. 4. Coating agent for corrosion protection according to claim 1 - 3, characterized in that the hydraulic or highly hydraulic lime is preferred present in grain sizes between about 20 and about 50 .mu.m. 5. Coating agent for corrosion protection according to claim 1 - 4, characterized in that the Ilydraulic or Ilochhydraulic lime as aqueous suspension, preferably with a low water content, is present, which optionally Contains common fillers and additives. 6. Coating agent for corrosion protection according to claim 5, characterized in that the suspension contains further inorganic binders, in particular Contains Portland cement clinker powder and / or air lime. 7. Coating agents for corrosion protection according to claim 1 - 4, characterized in that the hydraulic or hydraulic lime in aqueous dispersion or emulsion of predominantly unsaponifiable plastics, if appropriate in a mixture with other pigments, customary fillers and auxiliaries and / or inorganic Binding agents, in particular Portland cement clinker powder and / or air lime, is present. 8. Coating agent for corrosion protection according to claim 1 - 4, characterized in that the IIydraulische or Ilochhydraulische Kalk usual solvent-based coating materials, preferably based on unsaponifiable materials bituminous materials and / or plastics, alone or in a mixture with other pigments, Fillers and / or inorganic binders, in particular Portland cement clinker powder and / or air lime is added. 9. Coating agent for corrosion protection according to claim 1 - 4, characterized in that the IJydraulische and Llochhydraulische Kalk are reaction-hindering non-resin binders, preferably epoxy resin, polyester resin, polymethyl methacrylate resin, alone or in a mixture with other pigments, fillers and / or inorganic Binding agents, in particular Portland cement clinker powder and / or air lime, added is.